子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | Closing cap of the Underground piping and wiring for the wire and cable detection test box equipped with an electronic means tamcheuk | KR20100108624 | 2010-11-03 | KR101118419B1 | 2012-03-06 | LEE DONG MAN; KIM IN KI |
| PURPOSE: A ground buried pipe of a test box having an electronic probe unit and a finishing cap of a wire cable for detecting a wire are provided to facilitate management by installing a finishing cap having an electronic probe unit in the end of a wire cable and monitoring the position of the cable. CONSTITUTION: A finishing cap(10) has a electric probe unit therein. A fixing unit clinches an electric cable(4). An open space for the electric cable is formed. A close adhesion member closely pressures the electric cable to an open space. | ||||||
| 162 | 자기력을 이용한 변형유기 상변태 측정 인장시험방법 및 장치 | KR1020100039978 | 2010-04-29 | KR1020110120531A | 2011-11-04 | 고강희; 이동열 |
| PURPOSE: A phase transformation measurement tension test method by using magnetic force and a test device thereof are provided to measure Martensitc generation by using a magnetic force measuring sensor. CONSTITUTION: A phase transformation measurement tension test method by using magnetic force comprises a tension unit(110), a body(120) and a magnetic measurement sensor(140). The tensile test pulls specimen(30) in an opposite direction. The tension unit is formed on the body. The magnetic measurement sensor is included in the tension unit and measures the magnetic force created in a specimen. The tension unit comprises a bottom jig(112), a top jig(114) and an ascending and descending bar(116). The lower part of the body is fixed to the bottom jig. | ||||||
| 163 | 나노 자성 입자 및 그를 이용한 급성 심근 경색증을 진단하는 방법 | KR1020100009136 | 2010-02-01 | KR1020110089643A | 2011-08-09 | 김영민 |
| PURPOSE: Magnetic nanoparticles and a method for diagnosing acute myocardiac infraction using the same are provided to combine antigen in blood with the myocardium indicator of the magnetic nanoparticles and measure the magnetic intensity of the magnetic nanoparticles. CONSTITUTION: Magnetic nanoparticles include superparamagnetic nanoparticle(110), a polymer film(120), and a myocardium indicator(130). The polymer film is coated on the outer circumference of the nanoparticle. The myocardium indicator is conjugated with the polymer film. The myocardium indicator is one of myoglobin, ck-mb, and cardiac troponin complex. The polymer film is formed based on hydrophilic polymeric materials. A method for diagnosing the acute myocardiac infraction includes the following: The magnetic nanoparticles are prepared. Blood is injected into the magnetic nanoparticles. The antigen in the blood is reacted with the myocardium indicator of the magnetic nanoparticles. Reacted magnetic nanoparticles are extracted. Magnetic field is applied to the extracted nanoparticles. The magnetic intensity of the magnetic nanoparticles is detected. Based on the detected magnetic intensity, the acute myocardiac infraction is diagnosed. | ||||||
| 164 | 투자율 측정 장치 | KR1020090119110 | 2009-12-03 | KR1020110062395A | 2011-06-10 | 이진이; 김정민; 이재선 |
| PURPOSE: A magnetic permeability measurement apparatus is provided to measure magnetic permeability of targets continuously inputted in a steel-making process line in a high speed, by measuring magnetic permeability accurately as using magnetic field with constant intensity. CONSTITUTION: A magnetic field generation part(21) applies magnetic field with constant intensity to a magnetic permeability measurement target. A first magnetic sensor(22a) is located around the magnetic permeability measurement target. A second magnetic sensor(22b) is located between the magnetic permeability measurement target and the first magnetic sensor. The second magnetic sensor generates a differential output voltage together with the first magnetic sensor. A conversion part(24) converts the differential output voltage into magnetic permeability. A display part(25) displays the magnetic permeability. | ||||||
| 165 | 와전류 센서의 금속 모재선별 방법 및 장치 | KR1020050054707 | 2005-06-23 | KR1020060134764A | 2006-12-28 | 고각현 |
| A method and an apparatus for classifying a base metal of an eddy current sensor are provided to improve accuracy of the eddy current sensor by compensating an error of the sensing result due to different properties of the base metal. An apparatus for classifying a base metal of an eddy current sensor includes a current/voltage measuring unit, an impedance/phase difference measuring unit, an inductance/actual resistance measuring unit, and a classifying unit. The current/voltage measuring unit measures the current and voltage of an eddy current sensor coil unit. The impedance/phase difference measuring unit measures the impedance and phase difference of the eddy current sensor coil unit. The inductance/actual resistance measuring unit extracts the variation of the inductance and actual resistance of the eddy current sensor coil unit. The classifying unit compares the variation of the inductance/actual resistance of the eddy current sensor coil unit with impedance variation data of the eddy current sensor coil unit to classify the base metal for the eddy current sensor. | ||||||
| 166 | 비틀림 검출기 | KR1019900000804 | 1990-01-24 | KR1019930008305B1 | 1993-08-27 | 하마무라지요; 아께다히데오; 사또히로시; 우쯔이요시히꼬 |
| 내용 없음. | ||||||
| 167 | 금속편의 응력 및 결함감지용 검색센서 | KR1019840002410 | 1984-05-03 | KR1019850000677A | 1985-02-28 | 세포아이.티토 |
| 내용없음. | ||||||
| 168 | HYDROGEL SENSOR ASSEMBLY | US16221003 | 2018-12-14 | US20190231218A1 | 2019-08-01 | Prashant Tathireddy; Rohit Sharma; Seung Hei Cho; Nicholas Frazier; Yoosung Goo |
| A hydrogel sensor device can include a crosslinked hydrogel body which changes in volume in response to an environmental stimulus, a support post positioned to mechanically support the crosslinked hydrogel body during the change in volume, and a sensor positioned to detect the change in volume in the crosslinked hydrogel body. | ||||||
| 169 | NEAR-FIELD DEVICE | US15642168 | 2017-07-05 | US20190013839A1 | 2019-01-10 | Anthony Kerselaers; Pieter Verschueren; Liesbeth Gommé |
| One example discloses a near-field device, comprising: a near-field receiver coupled to a near-field receiver antenna and a decoder circuit; wherein the near-field receiver antenna is configured to be capacitively coupled at a first location of a first substance; wherein the near-field receiver antenna is configured to receive a first near-field signal from the first substance through the receiver's capacitive coupling; and wherein the decoder circuit is configured to compare an attribute of the first near-field signal to an attribute of a second near-field signal received from a second substance. | ||||||
| 170 | TEMPERATURE CONTROLLED MAGNETIC PERMEABILITY DETECTOR | US15777311 | 2016-12-01 | US20180348312A1 | 2018-12-06 | Khaled TERIKE; Filiz IBRAIMI |
| A device for detection of magnetic permeability (μ) or, alternatively, relative magnetic permeability (μr) or, alternatively relative magnetic susceptibility (μr-) of a sample is described. The device comprises a sample chamber having at least one opening for introduction of a sample or a sample container holding a sample and an electronic circuit. The device also comprises a coil surrounding said sample chamber, and also an electronic circuit adapted to measure the inductance of said coil. The sample chamber, coil and at least one component of the electronic circuit are placed in a temperature controlled zone. Said at least one component in said electronic circuit is/are selected from the group consisting of capacitors, sensors, precision voltage references, precision regulators, low pass and or high pass filters. | ||||||
| 171 | Inspection device and method for disposing magneto-optical crystal | US15314657 | 2015-06-02 | US10139370B2 | 2018-11-27 | Tomonori Nakamura |
| An inspection device includes a light source, an MO crystal disposed to face a semiconductor device (D), an object lens configured to concentrate the light output from the light source onto the MO crystal, a holder configured to hold the MO crystal, a flexible member interposed between the MO crystal and the holder, and an object lens drive unit configured to cause the MO crystal to contact the semiconductor device (D) by causing the holder to be moved in the optical axis direction of the object lens, wherein, when the MO crystal contacts the semiconductor device (D), the flexible member is bent, so that an incident plane is inclined in a range in which an inclination angle of the incident plane of the light in the MO crystal with respect to a plane orthogonal to the optical axis is less than or equal to an aperture angle. | ||||||
| 172 | FOREIGN-MATTER INSPECTION DEVICE | US15764592 | 2016-09-30 | US20180321166A1 | 2018-11-08 | Takuya YAEGASHI; Takayuki TANAKA |
| A foreign-matter inspection device includes a transporting unit transporting an object to be inspected, an X-ray inspection unit detecting a foreign matter included in the object transported by the transporting unit by using permeability of X-rays, a metal detection unit detecting a foreign matter included in the object transported by the transporting unit by using an interaction between a magnetic field and a metal, and a housing accommodating the X-ray inspection unit, the metal detection unit, and at least a part of the transporting unit therein and keeping the X-rays of the X-ray inspection unit from leaking outside. The housing is provided with a door part opening and closing the housing. The door part abuts against the housing via an insulating body in a closed state. | ||||||
| 173 | FOREIGN-MATTER INSPECTION DEVICE AND FOREIGN-MATTER INSPECTION SYSTEM | US15764523 | 2016-09-30 | US20180313772A1 | 2018-11-01 | Takuya YAEGASHI; Ryo TANAKA |
| A foreign-matter inspection device includes a transporting unit transporting an object to be inspected, an X-ray inspection unit detecting a foreign matter included in the object transported by the transporting unit by using permeability of X-rays, a metal detection unit detecting a foreign matter included in the object transported by the transporting unit by using an interaction between a magnetic field and a metal, a housing accommodating the X-ray inspection unit, the metal detection unit, and at least a part of the transporting unit therein, and a data management unit storing result data of the X-ray inspection unit and result data of the metal detection unit in a storage unit in association with each other. | ||||||
| 174 | Apparatus, system, and method for monitoring flow in a passage | US15901717 | 2018-02-21 | US10114000B1 | 2018-10-30 | Meade Lewis; Justin Stewart |
| An assembly for sensing flow material in a passage of a member is disclosed. The assembly has a housing, a communication device disposed at least partially in the housing, and a controller disposed at least partially in the housing. The assembly also has a sensor array disposed at least partially in the housing, and an external-surface-mounting attachment portion configured to non-intrusively attach the assembly to a surface. The sensor array includes a pressure sensor, a density sensor, a corrosion sensor, and a vibration sensor. The controller controls the communication device to transmit sensed data collected by the sensor array at a frequency of between about one transmission per second and about fifty transmissions per second. | ||||||
| 175 | DETECTING APPARATUS, POWER RECEIVING APPARATUS, POWER TRANSMITTING APPARATUS, AND CONTACTLESS POWER SUPPLY SYSTEM | US16019708 | 2018-06-27 | US20180309327A1 | 2018-10-25 | TAKASHI MIYAMOTO; KOHEI MORI; TOMOMICHI MURAKAMI |
| There is provided a detecting apparatus including one or a plurality of magnetic coupling elements that include a plurality of coils, and a detector that measures an electrical parameter related to the one or plurality of magnetic coupling elements or to a circuit that at least includes the one or plurality of magnetic coupling elements, and determines from a change in the electrical parameter whether a foreign matter that generates heat due to magnetic flux is present. In the one or plurality of magnetic coupling elements, the plurality of coils are electrically connected such that magnetic flux produced from at least one or more of the plurality of coils and magnetic flux produced from remaining coils of the plurality of coils have approximately opposing orientations. | ||||||
| 176 | SYSTEM FOR GENERATING A VECTOR MAGNETIC FIELD | US15944127 | 2018-04-03 | US20180301261A1 | 2018-10-18 | Antoine DAËL; Pascal LAVIE |
| A system for generating a magnetic field orientable in three dimensions configured to be integrated in a test vessel in which an ultra-high vacuum medium reigns, the system for generating a vector magnetic field being including superconducting coils, a cooling system making it possible to cool the superconducting coils to a superconducting temperature; a leaktight case, leaktight to the ultra-high vacuum and compatible with the ultra-high vacuum, the leaktight case enclosing the superconducting coils and being cooled by the cooling system; a heat shield compatible with the ultra-high vacuum surrounding the leaktight case. | ||||||
| 177 | System and Method of Identifying a Module in a Stack Light | US15489289 | 2017-04-17 | US20180299370A1 | 2018-10-18 | Will J. Preischel; John P. Caspers; Patrick K. Duffy |
| A system to verify the identity of modules within a stack light is disclosed. A sensor is mounted to a circuit board inserted within a housing of the module, and a target is mounted to or integrally formed in the housing. The sensor detects and generates a signal corresponding to the detected target. Different targets or locations for the target are provided for each housing. The module, a base for the stack light, or a remote controller in communication with the stack light identifies the housing in which the circuit board is mounted based on the feedback signal generated by detecting the target. At power-up, a routine may initiate a verification routine by which each module in the stack light determines the type of housing in which the circuit board for that module is located. | ||||||
| 178 | MAGNETIC SENSOR, BIOLOGICAL CELL SENSING DEVICE, AND DIAGNOSTIC DEVICE | US15698372 | 2017-09-07 | US20180271395A1 | 2018-09-27 | Hitoshi IWASAKI; Akira KIKITSU; Satoshi SHIROTORI |
| According to one embodiment, a magnetic sensor includes a first sensor element and a first interconnect. The first sensor element includes a first magnetic layer, a first opposing magnetic layer, and a first nonmagnetic layer provided between the first magnetic layer and the first opposing magnetic layer. A first magnetization of the first magnetic layer is aligned with a first length direction crossing a first stacking direction from the first magnetic layer toward the first opposing magnetic layer. At least a portion of the first interconnect extends along the first length direction. The first interconnect cross direction crosses the first length direction and is from the first sensor element toward the portion of the first interconnect. A first electrical resistance of the first sensor element changes according to an alternating current flowing in the first interconnect and a sensed magnetic field applied to the first sensor element. | ||||||
| 179 | Gas-sensitive hall device | US15247336 | 2016-08-25 | US10082484B2 | 2018-09-25 | Werner Breuer; Markus Eckinger |
| A chemically sensitive Hall device is described herein. In accordance with one example of the present invention, a Hall device comprises a substrate and a chemically sensitive layer arranged on the substrate. The chemically sensitive layer is able to interact with atoms or molecules of a gaseous or liquid fluid. Force electrodes are connected to the chemically sensitive layer for feeding a sensor current through the chemically sensitive layer along a first direction. Sense electrodes are connected to the chemically sensitive layer to tap a Hall voltage at the chemically sensitive layer along a second direction. A back gate is arranged on or integrated in the substrate and is isolated from the chemically sensitive layer by an isolation layer. | ||||||
| 180 | IDENTIFICATION OF MOLECULES BASED ON FREQUENCY RESPONSES USING ELECTROMAGNETIC WRITE-HEADS AND MAGNETO-RESISTIVE SENSORS | US15963006 | 2018-04-25 | US20180246176A1 | 2018-08-30 | Allen K. Bates; Anna W. Topol; Daniel J. Winarski |
| The inventive concepts presented herein relate to methods of identifying molecules identification of molecules using apparatuses including: electromagnetic write-head(s); magneto-resistive read sensor(s), and processor(s). An exemplary method includes magnetically exciting a molecule to be identified using an alternating magnetic field generated by an electromagnetic write-head, measuring a resonant response of the molecule to be identified using a magneto-resistive read sensor; and comparing, using a processor, the resonant response of the molecule to be identified with a table of known resonant responses to identify a chemical composition of the molecule to be identified. The molecule to be identified may optionally be disposed on a biosample substrate which comprises, or is coupled to, a plurality of servo-alignment marks; and the plurality of servo-alignment marks are configured to facilitate alignment of the electromagnetic write-head with the biosample tracks of the biosample substrate. | ||||||
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